A light diffraction element comprising a transparent substrate and a first orientation layer that is formed on one surface of the substrate and includes anisotropic polymers and a first pattern of an orientation direction arranged periodically in a first direction along the primary plane of the substrate. The first pattern includes three or more small regions that are arranged in the first direction and in which the orientation direction of the polymers included in the first orientation layer are different from each other, and generates diffracted light as a result of interference between light passed respectively through the three or more small regions.
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24. A light diffraction element comprising:
a transparent substrate;
a first orientation layer that is formed on one surface of the substrate and includes anisotropic polymers and a first pattern of an orientation direction arranged periodically in a first direction along the primary plane of the substrate;
a first liquid crystal layer that is provided on the first orientation layer and includes liquid crystal oriented periodically in the orientation direction of the first orientation layer;
a second orientation layer that is formed on a top surface of the first liquid crystal layer and includes anisotropic polymers and a second pattern of an orientation direction arranged periodically in a second direction along the primary plane of the substrate; and
a second liquid crystal layer that is provided on the second orientation layer and includes liquid crystal periodically oriented in the orientation direction of the second orientation layer, wherein
the first pattern is formed to have an orientation direction that changes while moving in the first direction, and generates diffracted light as a result of interference between light passed through the first pattern,
the total of retardation of the first orientation layer and retardation of the first liquid crystal layer is a ½ wavelength, and
the total of retardation of the second orientation layer and retardation of the second liquid crystal layer is a ¼ wavelength.
15. A light diffraction element comprising:
a transparent substrate;
a first orientation layer that is formed on one surface of the substrate and includes anisotropic polymers and a first pattern of an orientation direction arranged periodically in a first direction along the primary plane of the substrate;
a first liquid crystal layer that is provided on the first orientation layer and includes liquid crystal oriented periodically in the orientation direction of the first orientation layer;
a second orientation layer that is formed on a top surface of the first liquid crystal layer and includes anisotropic polymers and a second pattern of an orientation direction arranged periodically in a second direction along the primary plane of the substrate; and
a second liquid crystal layer that is provided on the second orientation layer and includes liquid crystal periodically oriented in the orientation direction of the second orientation layer, wherein
the first pattern is formed to have an orientation direction that changes while moving in the first direction, and generates diffracted light as a result of interference between light passed through the first pattern,
the total of retardation of the first orientation layer and retardation of the first liquid crystal layer is a ¼ wavelength, and
the total of retardation of the second orientation layer and retardation of the second liquid crystal layer is a ½ wavelength.
13. A light diffraction element comprising:
a transparent substrate;
a first orientation layer that is formed on one surface of the substrate and includes anisotropic polymers and a first pattern of an orientation direction arranged periodically in a first direction along the primary plane of the substrate;
a first liquid crystal layer that is provided on the first orientation layer and includes liquid crystal oriented periodically in the orientation direction of the first orientation layer;
a second orientation layer that is formed on a top surface of the first liquid crystal layer and includes anisotropic polymers and a second pattern of an orientation direction arranged periodically in a second direction along the primary plane of the substrate; and
a second liquid crystal layer that is provided on the second orientation layer and includes liquid crystal periodically oriented in the orientation direction of the second orientation layer, wherein
the first pattern includes three or more small regions that are arranged in the first direction and in which the orientation direction of the polymers included in the first orientation layer are different from each other, and generates diffracted light as a result of interference between light passed respectively through the three or more small regions,
the total of retardation of the first orientation layer and retardation of the first liquid crystal layer is a ½ wavelength, and
the total of retardation of the second orientation layer and retardation of the second liquid crystal layer is a ¼ wavelength.
1. A light diffraction element comprising:
a transparent substrate;
a first orientation layer that is formed on one surface of the substrate and includes anisotropic polymers and a first pattern of an orientation direction arranged periodically in a first direction along the primary plane of the substrate;
a first liquid crystal layer that is provided on the first orientation layer and includes liquid crystal oriented periodically in the orientation direction of the first orientation layer;
a second orientation layer that is formed on a top surface of the first liquid crystal layer and includes anisotropic polymers and a second pattern of an orientation direction arranged periodically in a second direction along the primary plane of the substrate; and
a second liquid crystal layer that is provided on the second orientation layer and includes liquid crystal periodically oriented in the orientation direction of the second orientation layer, wherein
the first pattern includes three or more small regions that are arranged in the first direction and in which the orientation direction of the polymers included in the first orientation layer are different from each other, and generates diffracted light as a result of interference between light passed respectively through the three or more small regions,
the total of retardation of the first orientation layer and retardation of the first liquid crystal layer is a ¼ wavelength, and
the total of retardation of the second orientation layer and retardation of the second liquid crystal layer is a ½ wavelength.
2. The light diffraction element according to
the second pattern is formed by arranging three or more small regions, in which the orientation direction of polymers included in the second orientation layer are different from each other, in the second direction,
the first direction and the second direction intersect,
the incident light is diffracted in the first direction as a result of interference between light passed respectively through the first orientation layer and the first liquid crystal layer, and
the incident light is diffracted in the second direction as a result of interference between light passed respectively through the second orientation layer and the second liquid crystal layer.
3. The light diffraction element according to
a ¼ wavelength retardation layer is provided between the first liquid crystal layer and the second orientation layer.
4. The light diffraction element according to
the first direction and the second direction are orthogonal.
5. The light diffraction element according to
width of the first pattern in the first direction is equal to width of the second pattern in the second direction.
6. The light diffraction element according to
the second orientation layer is a hardened light orienting compound.
7. The light diffraction element according to
widths of the small regions of the second pattern in the second direction are the same as each other.
8. The light diffraction element according to
the second pattern includes a stripe pattern in which the small regions are arranged in the second direction.
9. The light diffraction element according to
wherein
the second pattern is formed such that the orientation direction changes when moving in the second direction,
the first direction and the second direction intersect,
the incident light is diffracted in the first direction as a result of interference between light passed respectively through the first orientation layer and the first liquid crystal layer, and
the incident light is diffracted in the second direction as a result of interference between light passed respectively through the second orientation layer and the second liquid crystal layer.
10. The light diffraction element according to
the first direction and the second direction form an angle of 45°.
11. The light diffraction element according to
width of the second pattern in the second direction is 21/2 times width of the first pattern in the first direction.
14. The light diffraction element according to
the second pattern is formed by arranging three or more small regions, in which the orientation direction of polymers included in the second orientation layer are different from each other, in the second direction,
the first direction and the second direction intersect,
the incident light is diffracted in the first direction as a result of interference between light passed respectively through the first orientation layer and the first liquid crystal layer, and
the incident light is diffracted in the second direction as a result of interference between light passed respectively through the second orientation layer and the second liquid crystal layer.
16. The light diffraction element according to
the second pattern is formed such that the orientation direction changes when moving in the second direction,
the first direction and the second direction intersect,
the incident light is diffracted in the first direction as a result of interference between light passed respectively through the first orientation layer and the first liquid crystal layer, and
the incident light is diffracted in the second direction as a result of interference
between light passed respectively through the second orientation layer and the
second liquid crystal layer.
17. The light diffraction element according to
the first direction and the second direction are orthogonal.
18. The light diffraction element according to
the second orientation layer is a hardened light orienting compound.
19. The light diffraction element according to
a ¼ wavelength retardation layer is provided between the first liquid crystal layer and the second orientation layer.
20. The light diffraction element according to
width of the first pattern in the first direction is equal to width of the second pattern in the second direction.
21. The light diffraction element according to
the first direction and the second direction form an angle of 45°.
22. The light diffraction element according to
width of the second pattern in the second direction is 2½times width of the first pattern in the first direction.
25. The light diffraction element according to
the second pattern is formed such that the orientation direction changes when moving in the second direction,
the first direction and the second direction intersect,
the incident light is diffracted in the first direction as a result of interference between light passed respectively through the first orientation layer and the first liquid crystal layer, and
the incident light is diffracted in the second direction as a result of interference between light passed respectively through the second orientation layer and the second liquid crystal layer.
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The contents of the following Japanese patent applications and PCT application are incorporated herein by reference:
1. Technical Field
The present invention relates to a light diffraction element and an optical low pass filter using the light diffraction element.
2. Related Art
An optical low pass filter is used for a digital movie or digital camera using an image capturing element in order to prevent Moire patterns caused by input of an optical image having a spatial frequency higher than the pixel pitch of the image capturing element. A liquid crystal board utilizing birefringence of a material is used as an optical low pass filter, as shown in Patent Document 1.
Patent Document 1: International Publication No. 2008/004570
However, a light diffraction element using a crystal board has an increased thickness, and is therefore difficult to miniaturize. Furthermore, a crystal board is expensive, and easily attracts debris due to its charge.
Therefore, it is an object of an aspect of the innovations herein to provide a light diffraction element and an optical low pass filter, which are capable of overcoming the above drawbacks accompanying the related art. The above and other objects can be achieved by combinations described in the claims.
According to a first aspect of the present invention, provided is a light diffraction element comprising a transparent substrate and a first orientation layer that is formed on one surface of the substrate and includes anisotropic polymers and a first pattern of an orientation direction arranged periodically in a first direction along the primary plane of the substrate. The first pattern includes three or more small regions that are arranged in the first direction and in which the orientation direction of the polymers included in the first orientation layer are different from each other, and generates diffracted light as a result of interference between light passed respectively through the three or more small regions.
According to a second aspect of the present invention, provided is a light diffraction element comprising a transparent substrate and a first orientation layer that is formed on one surface of the substrate and includes anisotropic polymers and a first pattern of an orientation direction arranged periodically in a first direction along the primary plane of the substrate. The first pattern is formed to have an orientation direction that changes while moving in the first direction, and generates diffracted light as a result of interference between light passed through the first pattern.
According to a third aspect of the present invention, provided is an optical low pass filter that uses the light diffraction element described above.
The summary clause does not necessarily describe all necessary features of the embodiments of the present invention. The present invention may also be a sub-combination of the features described above.
Hereinafter, some embodiments of the present invention will be described. The embodiments do not limit the invention according to the claims, and all the combinations of the features described in the embodiments are not necessarily essential to means provided by aspects of the invention.
The substrate 200 has an overall substantially uniform thickness. For example, the substrate 200 may be formed as a rectangle with dimensions of 2 mm to 5 mm by 2 mm to 5 mm. A transparent glass substrate with a high transmittance for visible light wavelengths can be used as the substrate 200. The substrate 200 may be formed by transparent material such as resin material including a board made of resin, a film made of resin, or glass fiber.
The first orientation layer 202 is formed by an anisotropic polymer. In the first orientation layer 202, a first pattern 212, which is a polymer arrangement pattern, is repeatedly arranged periodically in the ±x direction along the primary plane of the substrate 200. The width of each first pattern 212 in the ±x direction can be set as needed such that predetermined diffracted light is generated from the incident light, and can be set to a value from 0.5 μm to 1000 μm, for example. Here, the property of being anisotropic includes both having an anisotropic optical refractive index and having an anisotropic optical absorption rate.
In the small regions 214, the polymers are arranged with a prescribed orientation direction 220, and the polymers in adjacent small regions 214 have different orientation directions 220 from each other. In the example shown in
The polymers of the small regions 214 are not particularly limited, as long as they are formed of a material whose orientation can be controlled, and may be light-reactive liquid crystal compounds or light orienting compounds such as light-splitting, optical double-quantum, or optical anisotropic type compounds. After these compounds are oriented in a predetermined direction, the compounds may be hardened by light or heat to fix the orientation direction. The same material may be used as the polymers for the entire first orientation layer 202, or different polymers may be used for each small region 214.
The first liquid crystal layer 204 on the small region 214 is oriented in the orientation direction 220 of the small region 214. In other words, the first liquid crystal layer 204 is oriented in the orientation direction of the first orientation layer 202 that is directly below the first liquid crystal layer 204. In this way, the first liquid crystal layer 204 has a pattern in which the direction of the retardance axis of the birefringence is arranged periodically according to the orientation of the first orientation layer 202. By periodically changing the direction of the retardance axis according to the position, the first liquid crystal layer 204 functions as a phase diffraction grating. Polymeric liquid crystal formed by optical or thermal polymerization may be used as the first liquid crystal layer 204. The first liquid crystal layer 204 has a thickness of approximately 0.01 μm to 1 μm, for example. The same crystal material may be used for the entire first liquid crystal layer 204, or different liquid crystal material may be used for each region corresponding to a small region 214.
The total of the retardation of the first orientation layer 202 and the retardation of the first liquid crystal layer 204 is a ½ wavelength, for example.
In the light diffraction element 104 described above, the incident light 400 that is incident from the +z direction in
As described above, in the light diffraction element 104, the first orientation layer 202 includes small regions 214 with different orientations from each other and the first liquid crystal layer 204 includes regions corresponding to the small regions 214, and therefore the lights passed through these small regions 214 interfere with each other to create diffracted light. Furthermore, in the first orientation layer 202, the first pattern 212 formed by the small regions 214 is repeated and the first liquid crystal layer 204 has a region corresponding to the repeating first pattern 212, and therefore the intensity of the diffracted light can be improved. Yet further, by setting the same angular difference between orientation directions 220 in adjacent small regions 214, the intensity ratio of the first-order diffracted light can be improved. When the orientation direction 220 of each first pattern 212 is rotated once or approximately once in the primary plane of the substrate 200, the intensity ratio of the first-order diffracted light can be increased. By setting the widths d1, d2, and d3 of the small regions 214 to be the same, the intensity ratio of the first-order diffracted light can be increased.
If the diffracted light can be created using only the first orientation layer 202, there is no need to provide the first liquid crystal layer 204. In this case, by orienting the retardance axes or absorption axes of the polymers in the small region 214 in a prescribed direction in the small regions 214, the refractive index anisotropy within the surface or refractive index anisotropy in the thickness direction can be realized. In the example shown in
The orientation direction of each region in the small regions 214 is changed by rotating the orientation direction 220 of the polymers of the small regions 214 in the primary plane of the substrate 200 in
With the embodiment described above, the light diffraction element 104 uses the first orientation layer 202 and the first liquid crystal layer 204, and can therefore be miniaturized. Furthermore, since there is no need to form bumps or depressions on the substrate 200 or the like, the flatness of the light diffraction element 104 can be improved. As a result, the light diffraction element 104 can achieve a sufficient aberration in the surface transmitting the wave, without providing cover glass or the like. Furthermore, since there is no need to form bumps or depressions on the substrate 200, the effects of debris such as dust is reduced. As a result, maintenance is easier, manufacturability is improved, and the deterioration of optical characteristics caused by dust or the like can be restricted in the light diffraction element 104.
In
The directions to which the orientation direction of the polymers are changed is the same ±x direction as the arrangement direction of the first pattern 212. Furthermore, the orientation direction changes smoothly at the border between first patterns. In the overall light diffraction element 104 of the present embodiment, the orientation direction of the polymers changes periodically in a continuous manner in the ±x direction.
The polymer orientation direction is rotated by 180° in each one of the first patterns 212. By rotating the orientation direction by 180° in the primary plane of the substrate 200 for each first pattern, the intensity ratio of the first-order diffracted light can be improved. This is because the light interference effect enables the first-order diffracted light to be efficiently output.
In the present embodiment, the orientation direction in the first pattern 212 is changed by rotating the orientation direction of the polymers of the first patterns 212 within the primary plane of the substrate 200 shown in
In the present embodiment, the total of the retardation of the first orientation layer 202 and the retardation of the first liquid crystal layer 204 is a ½ wavelength, for example.
A plurality of orientation patterns of the first orientation layer 202 and the first liquid crystal layer 204 in
In a single first pattern 212, the orientation direction 220 is different for adjacent small regions 214. For example, the four small regions 214 included in one first pattern 212 are arranged such that the orientation directions 220 thereof are rotated once. In the example of
By changing the orientation direction 220 such that the angle difference between adjacent small regions 214 adjacent clockwise or counter-clockwise in the ±y direction is the same, the intensity ratio of the first-order diffracted light can be improved.
The first liquid crystal layer 204 is arranged in the orientation direction of the first orientation layer 202 located directly therebelow. In other words, the liquid crystal molecules in the first liquid crystal layer 204 are oriented according to the first pattern 212 of the first orientation layer 202, in each region of the matrix pattern formation.
In the light diffraction element 104 described above, the incident light 400 that is incident from the positive ±z direction in
In the example of
In
With the embodiment described above, since the first orientation layer 202 and the first liquid crystal layer 204 used have orientation directions that change periodically in the ±x direction and the ±y direction, the light diffraction element 104 can be miniaturized and the diffracted light separated into directions orthogonal to each other in the surface of the substrate 200 can be output.
The left side of
The light diffraction element 104 shown in
The first orientation layer 202 includes anisotropic polymers. The second orientation layer 208 includes anisotropic polymers that are the same as or different from those included in the first orientation layer 202. These anisotropic polymers are oriented with a periodic pattern in the first orientation layer 202 and the second orientation layer 208. In the same manner as the first to third embodiments, a plurality of first patterns 212 formed of small regions defining a minimum unit region of an orientation pattern are formed in the first orientation layer 202 and these first patterns 212 are arranged periodically in the ±x direction, which is a first direction, along the primary plane of the substrate 200. In the second orientation layer 208, second patterns 216 formed of small regions defining a minimum unit region of an orientation pattern are arranged periodically in the ±y direction, which is a second direction intersecting the first direction, along the primary plane of the substrate.
The ±x direction and the ±y direction are not particularly limited, as long as these directions are not the same, and can be orthogonal to each other, for example. By setting the ±x direction and the ±y direction to be orthogonal, the first-order diffracted light can be separated into four or more directions.
The first pattern of the first orientation layer 202 and the second pattern of the second orientation layer 208 can be formed to be the same as the first pattern 212 described above in the first to third embodiments. The second pattern can be formed by switching the first direction with the second direction in the first pattern described above in the first to third embodiments.
The first liquid crystal layer 204 is oriented according to the orientation direction of the first orientation layer 202 located directly therebelow. The first liquid crystal layer 204 is oriented in a pattern corresponding to the first pattern of the first orientation layer 202. The total of the retardation of the first orientation layer 202 and the retardation of the first liquid crystal layer 204 is a ½ wavelength, for example.
The retardation layer 206 converts the circularly polarized diffracted light emitted from the second pattern 216 into linearly polarized light. A ¼ wavelength retardation layer, for example, can be used as the retardation layer 206. A ¼ wavelength plate converts the linearly polarized light into circularly polarized light, and also converts circularly polarized light into linearly polarized light. The ¼ wavelength plate preferably has positive wavelength dispersion characteristics, in order to decrease the effect of diffracted light intensity distribution caused by color. For example, the retardation layer 206 having positive waveform dispersion characteristics (inverse dispersion) can be formed by layering a plurality of layers with different optical axes and phase differences. The retardation layer 206 can have a thickness of approximately 0.01 μm to 5 μm, for example.
The retardation layer 206 can be formed by causing a variety of liquid crystals to have prescribed orientations. For example, a liquid crystal layer can be formed by forming an orientation film using a method of optical orientation of rubbing in advance and then applying birefringent liquid crystal (e.g. a material used above when describing the first liquid crystal layer), and the resulting liquid crystal layer can be used as the retardation layer 206. If polymeric liquid crystal is used as the liquid crystal, the polymerization reaction progresses due to light or heat, thereby hardening the liquid crystal.
The retardation layer may be formed by transposing and affixing a ¼ wavelength plate prepared in advance as a sheet onto the first orientation layer or onto liquid crystal provided on the first orientation layer through a method such as lamination.
The second liquid crystal layer 210 is oriented in the orientation direction of the second orientation layer 208 located directly therebelow. The second liquid crystal layer 210 is oriented with a pattern corresponding to the second pattern of the second orientation layer 208. The total of the retardation of the second orientation layer 208 and the retardation of the second liquid crystal layer 210 is a ½ wavelength, for example. The first liquid crystal layer 204 located above different first patterns 212 and the second liquid crystal layer 210 located above different second patterns 216 can include liquid crystal having the same composition but different orientation directions.
In this way, the light diffraction element generates diffracted light in the ±x direction and the ±y direction by passing the incident light 400 through the second liquid crystal layer 210, the second orientation layer 208, the retardation layer 206, the first liquid crystal layer 204, and the first orientation layer 202.
In the present embodiment, the widths of the first liquid crystal layer 204 and the first pattern 212 in the first direction are the same as the widths of the second liquid crystal layer 210 and the second pattern 216 in the second direction. Since the widths of the first pattern and the second pattern and the distance by which the first-order diffracted light beams are separated from each other have a relationship that is approximately inversely proportionate, the light diffraction element 104 can output diffracted light beams that are separated to be positioned at the vertices of a substantially square shape.
If the light diffraction element 104 does not include the retardation layer 206, the circularly polarized diffracted light beams passed through the second liquid crystal layer 210 and the second orientation layer 208 are not sufficiently split by the first liquid crystal layer 204 and the first orientation layer 202, which results in diffracted light split into two beams being emitted, but in this case the light diffraction element 104 still functions as a light diffraction element.
In the embodiment shown in
With the embodiment described above, a simple configuration can be used to achieve the same effect as the embodiment described in
Next, the suitably dried first orientation layer 202 is exposed to light through a proximity technique using a mask with a UV light polarization device. As shown in
Next, the mask 500 is shifted in the +y direction by the width of a small region 214, and the small regions 214 that are adjacent to the small regions 214 of the first patterns 212 that were exposed to light immediately before are exposed to the polarized light 502 that is rotated by 60° within the xy plane relative to the polarization direction shown in
As shown by
As shown by
As shown by
The second orientation layer 208 is suitably dried and exposed to light through a proximity technique using a mask with a UV light polarization device. In this case, using the mask 500 including openings that extend in the ±y direction and are arranged in the ±x direction with a prescribed pitch, prescribed small regions among the small regions within the second patterns are exposed to the polarized light polarized in the ±y direction. In the light orienting compound in the small regions, the portions that are exposed to light orient the light to be parallel to the polarization direction.
Next, in the same manner as shown in
Furthermore, as shown by
In this way, the light diffraction element 104 is manufactured that can split incident light two-dimensionally into four beams. In addition, an anti-reflection film and protective film, for example, can be formed on the second liquid crystal layer 210. In this way, internal reflection can be prevented and the transmittance can be improved. Furthermore, an infrared reflective film that reflects infrared rays having a wavelength of 800 nm or more and a short wavelength reflective film that reflects wavelengths of 400 nm or less may be provided.
In the light diffraction element 104 manufacturing method described above, the second orientation layer 208 and the first orientation layer 202 functioning as the orientation film, the first liquid crystal layer 204 and the second liquid crystal layer 210 functioning as the diffraction element, and the retardation layer 206 functioning as the ¼ wavelength plate are formed on the same substrate 200. As a result, the thickness of each layer formed by the application of liquid crystal is lower than in a case where the ¼ wavelength plate and the diffraction element are formed as separate components and then assembled. As a result, the light diffraction element can be made thinner. Furthermore, since the steps of aligning and combining the first liquid crystal layer 204 and the second liquid crystal layer 210 are unnecessary, the manufacturing process can be simplified.
The left side of
In this way, the light diffraction element 304 according to the fifth embodiment does not include the retardation layer 206 between the first liquid crystal layer 204 and the second orientation layer 208 as in the light diffraction element 104 according to the fourth embodiment, and the second pattern 316 of the second orientation layer 308 is arranged at an incline relative to the first pattern 312. The substrate 200 and the first orientation layer 202 are substantially the same as in the light diffraction element 104 according to the fourth embodiment, and are therefore omitted from the description.
The first liquid crystal layer 306 is oriented in the orientation direction of the first orientation layer 202 located directly therebelow. The first liquid crystal layer 306 is oriented in a pattern corresponding to the first pattern 312 of the first orientation layer 202. The pattern of the first liquid crystal layer 306 is arranged periodically in the ±x direction, which is the first direction. The total of the retardation of the first orientation layer 202 and the retardation of the first liquid crystal layer 306 is a ¼ wavelength, for example.
The second orientation layer 308 is provided on the first liquid crystal layer 306 and orients the liquid crystal of the second liquid crystal layer 310. The second orientation layer 308 includes anisotropic polymers that are the same as or different from those in the first orientation layer 202. These anisotropic polymers are arranged in a periodic pattern in the second orientation layer 308.
In the second orientation layer 308, a plurality of second patterns, which are formed by small regions defining minimum unit regions of the orientation pattern, are arranged periodically in the second direction on the primary plane of the substrate. In the embodiment shown in
The second pattern 316 is divided into a plurality of small regions, in the same manner as the first pattern 312 of the first orientation layer 202. The small regions in the second pattern 316 are arranged in the second direction. By setting the direction in which the small regions are lined up to be the same as the direction in which the second patterns 316 are lined up, the small regions in which the orientation direction of the polymers changes periodically are repeated periodically in the second direction. For example, the second patterns 316 may be realized by rotating the first patterns 212 shown in
The second patterns 316 may be realized by changing the orientation direction along the second direction, in the same manner as the first patterns 212 according to the second embodiment. In this case, the second patterns 316 may be realized by rotating the first patterns 212 shown in
The second liquid crystal layer 310 is oriented in the orientation direction of the second orientation layer 308 located directly therebelow. The second liquid crystal layer 310 is oriented in a pattern corresponding to the second pattern of the second orientation layer 308. The total of the retardation of the second orientation layer 308 and the retardation of the second liquid crystal layer 310 is a ½ wavelength, for example.
Accordingly, the left circularly polarized light incident to the first liquid crystal layer 306 is split into left circularly polarized light that progresses as-is and right circularly polarized light that is diffracted at the bottom. Furthermore, the right circularly polarized light incident to the first liquid crystal layer 306 is split into right circularly polarized light that progresses as-is and left circularly polarized light that is diffracted at the top. Accordingly, the two circularly polarized light beams incident to the first liquid crystal layer 306 and the first orientation layer 202 become circularly polarized light split into four beams that are each in the ±x direction, which is the first direction. The circularly polarized light split into four beams is output from the substrate 200.
In the present embodiment, when an angle θ is formed by the first direction, which is the pattern arrangement direction of the first liquid crystal layer 306, and the second direction, which is the pattern arrangement direction of the second liquid crystal layer 310, the width of the second patterns in the second direction may be 2cosθ times the width of the first patterns in the first direction. Since the widths of the first patterns and the second patterns are approximately inversely proportional to the distance by which the first-order diffracted light beams are separated, in this case, the light diffraction element 304 can emit diffracted light that is split into beams located at the vertices of a substantially rectangular shape.
For example, since θ is 45° in the present embodiment, the width of each small region of the second patterns in the second direction may be 21/2 times the width of each small region in the first patterns in the first direction. In this way, the light diffraction element 304 can emit diffracted light that is split into beams located at the vertices of a substantially square shape.
In this way, the light diffraction element generates diffracted light in the ±x direction and the ±y direction by passing the incident light 400 through the second liquid crystal layer 310, the second orientation layer 308, the first liquid crystal layer 306, and the first orientation layer 202.
Instead of the present embodiment, an embodiment may be used in which the total of the retardation of the first orientation layer and the retardation of the first liquid crystal layer is a ½ wavelength and the total of the retardation of the second orientation layer and the retardation of the second liquid crystal layer is a ¼ wavelength.
The following shows an experimental example relating to the relationship between the width of adjacent small regions in the first direction in the first pattern and the first-order diffracted light efficiency of the light diffraction element.
In this experiment, the light diffraction element of the embodiment shown in
The widths of the small regions included in the second pattern 216 are expressed by the ratio between a and 10-1, in the same manner as in
When the experiment was performed using the above conditions, the relationship between the width (a) of the small region and the efficiency of the first-order diffracted light of the light diffraction element (the ratio of the total of the first-order diffracted light split into four beams within the total emitted light of the element) is as shown in the results of
According to
In the following,
In this experiment, the light diffraction element of the embodiment shown in
Here, each small region in the first orientation layer 202 has the same width, and the difference in the orientation direction of the polymers of adjacent regions is uniform. The second orientation layer 208 has the same pattern as the first orientation layer 202. The first orientation layer 202 and the second orientation layer 208 have a ½ wavelength retardation, and the retardation layer 206 has a ¼ wavelength retardation.
Upon performing the experiment with the above conditions, the first-order diffracted light efficiency of the light diffraction element was found to be 0.93. These results are shown in
This experiment uses the same conditions as the second experimental example, except that one first pattern is divided into six small regions. Specifically, the orientation direction of the polymers in the small regions are respectively 30°, 60°, 90°, 120°, 150°, and 180°.
Upon performing the experiment with the above conditions, the first-order diffracted light efficiency of the light diffraction element (the ratio of the total of the first-order diffracted light split into four beams within the total emitted light of the element) was found to be 0.83. These results are shown in
This experiment uses the same conditions as the second experimental example, except that one first pattern is divided into four small regions. Specifically, the orientation direction of the polymers in the small regions are respectively 45°, 90°, 135°, and 180°.
Upon performing the experiment with the above conditions, the first-order diffracted light efficiency of the light diffraction element (the ratio of the total of the first-order diffracted light split into four beams within the total emitted light of the element) was found to be 0.66. These results are shown in
This experiment uses the same conditions as the second experimental example, except that one first pattern is divided into three small regions. Specifically, the orientation direction of the polymers in the small regions are respectively 60°, 120°, and 180°.
Upon performing the experiment with the above conditions, the first-order diffracted light efficiency of the light diffraction element (the ratio of the total of the first-order diffracted light split into four beams within the total emitted light of the element) was found to be 0.47. These results are shown in
In this experiment, the light diffraction element of the embodiment shown in
Here, each small region in the first orientation layer 202 has the same width, and the difference in the orientation direction of the polymers of adjacent regions is uniform. The second orientation layer 208 has the same pattern as the first orientation layer 202. The first orientation layer 202 and the second orientation layer 208 have a ½ wavelength retardation, and the retardation layer 206 has a ¼ wavelength retardation. In the same manner as the fourth experimental example, each first pattern is divided into four regions, and the orientation direction of each small region is rotated by 45° when moving to an adjacent small region.
As shown in
While the embodiments of the present invention have been described, the technical scope of the invention is not limited to the above described embodiments. It is apparent to persons skilled in the art that various alterations and improvements can be added to the above-described embodiments. It is also apparent from the scope of the claims that the embodiments added with such alterations or improvements can be included in the technical scope of the invention.
The operations, procedures, steps, and stages of each process performed by an apparatus, system, program, and method shown in the claims, embodiments, or diagrams can be performed in any order as long as the order is not indicated by “prior to,” “before,” or the like and as long as the output from a previous process is not used in a later process. Even if the process flow is described using phrases such as “first” or “next” in the claims, embodiments, or diagrams, it does not necessarily mean that the process must be performed in this order.
Kakubari, Yuichi, Umezawa, Yasuaki, Watabe, Kenichi
Patent | Priority | Assignee | Title |
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